Device for self-assembling semiconductor light-emitting diodes

ABSTRACT

Discussed is a device for self-assembling semiconductor light-emitting diodes for placing the semiconductor light-emitting diodes at predetermined positions on a substrate by using an electric field and a magnetic field, the substrate being accommodated in an assembly chamber accommodating a fluid, the device including a substrate chuck configured to dispose the substrate at an assembly position, wherein the substrate chuck includes a substrate support part configured to support the substrate on which an assembly electrode is formed, a rotating part configured to support the substrate support part, and a controller configured to control driving of the substrate chuck, wherein the substrate support part includes micro-holes for injecting a gas between the fluid and the substrate, and wherein the controller controls whether the gas is injected through the micro-holes according to whether the substrate is raised or lowered.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a Continuation of U.S. patent application Ser. No. 16/842,347, filed on Apr. 7, 2020, which claims the benefit of earlier filing date and right of priority pursuant to 35 U.S.C. § 119(a), to Korean Application No. 10-2019-0115574, filed on Sep. 19, 2019, and Korean Application No. 10-2019-0120060, filed on Sep. 27, 2019, the entire contents of all these applications are hereby expressly incorporated by reference into the present application.

BACKGROUND OF THE INVENTION 1. Field of the Invention

The present disclosure relates to self-assembling in a method for manufacturing a display device, and more particularly, to a device for self-assembling microLEDs.

2. Description of the Related Art

In recent years, in the field of display technology, liquid-crystal displays (LCD), organic light-emitting diode (OLED) displays, microLED displays, etc. have been competing to realize large-area displays.

However, LCDs have problems such as slow response times and the low efficiency of light produced by a backlight, and OLEDs have disadvantages such as short lifetimes, low mass-production yields, and low efficiency.

On the contrary, semiconductor light-emitting diodes (microLEDs) with a diameter or cross-sectional area less than 100 IA, when used in displays, can offer very high efficiency because the displays do not need a polarizer to absorb light. However, large-scale displays require several millions of semiconductor light-emitting diodes, which makes it difficult to transfer the devices compared to other technologies.

Some of the technologies currently in development for the transfer process include pick & place, laser lift-off (LLO), and self-assembly. Among these technologies, the self-assembly approach is a method that allows semiconductor light-emitting diodes to find their positions on their own in a fluid, which is most advantageous in realizing large-screen display devices.

Recently, U.S. Pat. No. 9,825,202 disclosed a microLED structure suitable for self-assembly, but there is not enough research being carried out on technologies for manufacturing a display device by the self-assembly of microLEDs.

In view of this, the present disclosure proposes a new manufacturing device for self-assembling microLEDs.

SUMMARY OF THE INVENTION

One aspect of the present disclosure is to provide a manufacturing process having high reliability in a large screen display using a micro sized semiconductor light-emitting diode and a device used in the manufacturing process.

Another aspect of the present disclosure is to provide a structure of a substrate chuck capable of eliminating a cause of deteriorating an assembly yield during loading or unloading of a substrate in an assembly chamber to improve a self-assembly yield.

According to an embodiment of the present disclosure, in a device for self-assembling semiconductor light-emitting diodes for placing semiconductor light-emitting diodes at a predetermined position on a substrate accommodated in an assembly chamber accommodating a fluid by using an electric field and a magnetic field, the device for self-assembling semiconductor light-emitting diodes includes a substrate support part for supporting a substrate on which an assembly electrode is formed, a rotating part for rotating the substrate support part, a vertical moving part for moving the substrate supported by the substrate support part upwardly and downwardly to adjust a position of the substrate with respect to the fluid, an electrode connection part connected to the assembly electrode formed on the substrate to generate the electric field, and a controller for controlling driving of the substrate chuck, wherein the substrate support part includes microholes for sucking a gas present between the fluid and the substrate or injecting a gas into between the fluid and the substrate, and the controller controls whether the gas is sucked or injected through the microholes according to whether the substrate is raised or lowered.

In the present embodiment, when the substrate is lowered to be in contact with the fluid, the controller controls such that the gas present between the fluid and the substrate is sucked through the microholes, and when the substrate is raised so as to separate from the fluid, the controller controls such that the gas is injected into between the fluid and the substrate through the microholes.

In the present embodiment, the substrate support part includes a first frame for supporting one surface of the substrate on which the assembly electrode is formed and a second frame for supporting the other surface of the substrate.

In the present embodiment, the first frame includes a bottom portion having an opened central portion, and a sidewall portion formed at a predetermined height along an outer circumference of the bottom portion, and the microholes are formed at a predetermined pitch along at least a part of an inner circumference of the first frame.

In the present embodiment, the microholes are formed at least along a longitudinal direction of two sides facing each other among sides forming an inner circumference of the bottom portion.

In the present embodiment, the microholes formed along any one of the two sides facing each other suck the gas present between the fluid and the substrate, and the microholes formed along the other side of the two sides facing each other inject the gas into between the fluid and the substrate.

In the present embodiment, a mass flow control part for controlling an injection volume and an injection rate of the gas injected through the microholes is further included.

In the present embodiment, when the substrate is raised or lowered, the rotating part inclines the substrate such that one side of the substrate is in contact with the fluid first or separates from the fluid.

In the present embodiment, the microholes are formed at at least one side of the substrate support part for supporting one side of the substrate and the other side of the substrate support part for supporting the other side of the substrate facing the one side of the substrate.

The rotating part rotates the substrate support part around a width or longitudinal direction of the substrate such that vertical positions of the first frame and the second frame are switched.

According to an embodiment of the presented disclosure, a device for self-assembling semiconductor light-emitting diodes include a substrate chuck to dispose the substrate at an assembly position, the substrate chuck including a substrate support to support the substrate on which an assembly electrode is formed; a rotator to support the substrate support; a mover configured to move the substrate supported by the substrate support to adjust a position of the substrate with respect to a fluid; an electrode connector to connect to the assembly electrode formed on the substrate to generate the electric field; and a controller to control driving of the substrate chuck, wherein the substrate support includes microholes for extracting a gas present between the fluid and the substrate or injecting a gas between the fluid and the substrate, and wherein the controller controls whether the gas is extracted or injected through the microholes according to whether the substrate moved into or out of the fluid.

According to a device for self-assembling semiconductor light-emitting diodes according to an embodiment of the present disclosure, a gas (including bubbles) and a fluid confined to a substrate and a fluid surface are removed, and thus an assembly yield can be improved.

In addition, reliability of a self-assembly process can be ensured by an improved assembly yield, and the self-assembly process can be applied to a large area substrate.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a conceptual diagram showing one embodiment of a display device using semiconductor light-emitting diodes according to the present disclosure.

FIG. 2 is a partial enlarged view of the portion A in the display device of FIG. 1.

FIG. 3 is an enlarged view of the semiconductor light-emitting diodes of FIG. 2.

FIG. 4 is an enlarged view showing another embodiment of the semiconductor light-emitting diodes of FIG. 2.

FIGS. 5A to 5E are conceptual diagrams for explaining a new process for manufacturing the above-described semiconductor light-emitting diodes.

FIG. 6 is a conceptual diagram showing an example of a device for self-assembling semiconductor light-emitting diodes according to the present disclosure.

FIG. 7 is a block diagram of the self-assembly device of FIG. 6.

FIGS. 8A to 8E are conceptual diagrams showing a process for self-assembling semiconductor light-emitting diodes using the self-assembly device of FIG. 6.

FIG. 9 is a conceptual diagram for explaining the semiconductor light-emitting diodes of FIGS. 8A to 8E.

FIG. 10 is a flowchart showing a method for self-assembly according to the present disclosure.

FIG. 11 is a conceptual diagram showing a first state of a substrate chuck.

FIG. 12 is a conceptual diagram showing a second state of a substrate chuck.

FIG. 13 is a plan view of a first frame provided at a substrate chuck.

FIG. 14 is a conceptual diagram showing a state in which an assembly substrate is loaded at a substrate chuck.

FIG. 15 is a perspective view of a magnetic field forming part according to one embodiment of the present disclosure.

FIG. 16 is one side view of a magnetic field forming part according to one embodiment of the present disclosure.

FIG. 17 is a lower side view of a magnetic field forming part according to one embodiment of the present disclosure.

FIG. 18 is a conceptual diagram showing a trajectory of magnets provided at the magnetic field forming part according to the present disclosure.

FIG. 19 is a conceptual diagram showing a state in which a semiconductor light-emitting diode is supplied.

FIG. 20 is a plan view of an assembly chamber according to one embodiment of the present disclosure.

FIG. 21 is a cross-sectional view taken along line A-A′ of FIG. 20.

FIGS. 22 and 23 are conceptual views showing movement of a gate provided at an assembly chamber according to one embodiment of the present disclosure.

FIG. 24 is a conceptual diagram showing a warpage phenomenon of a substrate generated during self-assembly.

FIG. 25 is a conceptual diagram showing a method for correcting a warpage phenomenon of a substrate.

FIG. 26 is a flowchart showing a method for correcting a warpage phenomenon of a substrate.

FIG. 27 is a view showing a warpage phenomenon of a substrate that occurs during loading/unloading of a substrate.

FIG. 28 is an enlarged view of a portion in which microholes are formed in a substrate chuck according to an embodiment of the present disclosure.

FIG. 29 shows a process of sucking a gas between a substrate and a fluid during loading of a substrate.

FIG. 30 is a process of injecting a gas into between a substrate and a fluid during unloading of a substrate.

DETAILED DESCRIPTION OF THE EMBODIMENTS

Description will now be given in detail according to example embodiments disclosed herein, with reference to the accompanying drawings. For the sake of brief description with reference to the drawings, the same or equivalent components can be provided with the same or similar reference numbers, and description thereof will not be repeated. In general, a suffix such as “module” and “unit” can be used to refer to elements or components. Use of such a suffix herein is merely intended to facilitate description of the specification, and the suffix itself is not intended to give any special meaning or function. In the present disclosure, that which is well-known to one of ordinary skill in the relevant art has generally been omitted for the sake of brevity. The accompanying drawings are used to help easily understand various technical features and it should be understood that the embodiments presented herein are not limited by the accompanying drawings.

Also, it will be understood that when an element, such as a layer, area or substrate is referred to as being “disposed on” another element, the element can be disposed directly on the another element or there are no intervening elements present.

Mobile terminals described herein can include cellular phones, smart phones, laptop computers, digital broadcasting terminals, personal digital assistants (PDAs), portable multimedia players (PMPs), navigators, slate PCs, tablet PC, ultra books, digital TVs, digital signage, head-mounted displays (HMDs), desk top computers and the like. However, it can be easily understood by those skilled in the art that the configuration according to the example embodiments of this specification can also be applied to any device capable of displaying information even though such device is a new type of product to be developed.

FIG. 1 is a conceptual diagram showing one embodiment of a display device using semiconductor light-emitting diodes according to the present disclosure. FIG. 2 is a partial enlarged view of the portion A in the display device of FIG. 1. FIG. 3 is an enlarged view of the semiconductor light-emitting diodes of FIG. 2. FIG. 4 is an enlarged view showing another embodiment of the semiconductor light-emitting diodes of FIG. 2.

According to the illustration, information processed by a controller of a display device 100 can be outputted by a display module 140. A closed loop-shaped case 101 that runs around the edge of the display module can form the bezel of the display device.

The display module 140 comes with a panel 141 that displays an image, and the panel 141 can come with micro-sized semiconductor light-emitting diodes 150 and a wiring substrate 110 where the semiconductor light-emitting diodes 150 are mounted.

The wiring substrate 110 can be formed with wiring lines, which can be connected to n-type electrodes 152 and p-type electrodes 156 of the semiconductor light-emitting diodes 150. As such, the semiconductor light-emitting diodes 150 can be provided on the wiring substrate 110 as individual pixels that emit light on their own.

The image displayed on the panel 141 is visual information, which is rendered by controlling the light emission of unit pixels (sub-pixels) arranged in a matrix independently through the wiring lines.

The present disclosure takes microLEDs (light-emitting diodes) as an example of the semiconductor light-emitting diodes 150 which convert current into light. The microLEDs can be light-emitting diodes that are small in size—less than 100 microns. The semiconductor light-emitting diodes 150 have light-emitting regions of red, green, and blue, and unit pixels can produce light through combinations of these colors. That is, the unit pixels are the smallest units for producing one color. Each unit pixels can contain at least three microLEDs.

More specifically, referring to FIG. 3, the semiconductor light-emitting diodes 150 can have a vertical structure.

For example, the semiconductor light-emitting diodes 150 can be implemented as high-power light-emitting diodes that are composed mostly of gallium nitride (GaN), with some indium (In) and/or aluminum (Al) added to it, and emit light of various colors.

Such a vertical semiconductor light-emitting diode comprises a p-type electrode 156, a p-type semiconductor layer 155 formed on the p-type electrode 156, an active layer 154 formed on the p-type semiconductor layer 155, an n-type semiconductor layer 153 formed on the active layer 154, and an n-type electrode 152 formed on the n-type semiconductor layer 153. In this case, the p-type electrode 156 at the bottom can be electrically connected to a p electrode of the wiring substrate, and the n-type electrode 152 at the top can be electrically connected to an n electrode above the semiconductor light-emitting diode. One of the biggest advantages of the vertical semiconductor light-emitting diode 150 is that the chip size can be reduced by vertically aligning electrodes.

In another example, referring to FIG. 4, the semiconductor light-emitting diodes can be flip chip-type light-emitting diodes.

As an example of such a flip chip-type light-emitting diode, the semiconductor light-emitting diode 150′ comprises a p-type electrode 156′, a p-type semiconductor layer 155′ formed on the p-type electrode 156′, an active layer 154′ formed on the p-type semiconductor layer 155′, an n-type semiconductor layer 153′ formed on the active layer 154′, and an n-type electrode 152′ vertically separated from the p-type electrode 156′, on the n-type semiconductor layer 153′. In this case, both the p-type electrode 156′ and the n-type electrode 152′ can be electrically connected to a p electrode and n electrode of the wiring substrate, below the semiconductor light-emitting diode.

The vertical semiconductor light-emitting diode and a horizontal light-emitting diode each can be used as a green semiconductor light-emitting diode, blue semiconductor light-emitting diode, or red semiconductor light-emitting diode. The green semiconductor light-emitting diode and the blue semiconductor light-emitting diode can be implemented as high-power light-emitting diodes that are composed mostly of gallium nitride (GaN), with some indium (In) and/or aluminum (Al) added to it, and emit green and blue light, respectively. As an example of such high-power light-emitting diodes, the semiconductor light-emitting diodes can be composed of gallium nitride thin films which are formed of various layers of n-Gan, p-GaN, AlGaN, InGaN, etc. More specifically, the p-type semiconductor layer can be P-type GaN, and the n-type semiconductor layer can be N-type GaN.

Moreover, the p-type semiconductor layer can be P-type GaN doped with Mg on the p electrode, and the n-type semiconductor layer can be N-type GaN doped with Si on the n electrode. In this case, the above-described semiconductor light-emitting diodes can come without the active layer.

Meanwhile, referring to FIGS. 1 to 4, because of the very small size of the light-emitting diodes, self-emissive, high-definition unit pixels can be arranged on the display panel, and therefore the display device can deliver high picture quality.

In the above-described display device using semiconductor light-emitting diodes according to the present disclosure, semiconductor light-emitting diodes are grown on a wafer, formed through mesa and isolation, and used as individual pixels. In this case, the micro-sized semiconductor light-emitting diodes 150 should be transferred onto a wafer, at preset positions on a substrate of the display panel. One of the transfer technologies available is pick and place, but it has a low success rate and requires a lot of time. In another example, a number of diodes can be transferred at a time by using a stamp or roll, which, however, is not suitable for large-screen displays because of limited yields. The present disclosure suggests a new method and device for manufacturing a display device that can improve on these problems.

To this end, the new method for manufacturing a display device will be described first below. FIGS. 5A to 5E are conceptual diagrams for explaining a new process for manufacturing the above-described semiconductor light-emitting diodes.

In this specification, a display device using passive matrix (PM) semiconductor light-emitting diodes will be illustrated. It should be noted that the illustration given below also applies to active matrix (AM) semiconductor light-emitting diodes or other electrical devices. Also, although the illustration will be given of how horizontal semiconductor light-emitting diodes are self-assembled, it also can apply to self-assembling of vertical semiconductor light-emitting diodes and other electrical devices.

First of all, according to the manufacturing method, a first conductive semiconductor layer 153, an active layer 154, and a second conductive semiconductor layer 155 are grown on a growth substrate 159 (see FIG. 5A).

Once the first conductive semiconductor layer 153 is grown, then the active layer 154 is grown on the first conductive semiconductor layer 153, and then the second conductive semiconductor layer 155 is grown on the active layer 154. By sequentially growing the first conductive semiconductor layer 153, active layer 154, and second conductive semiconductor layer 155, the first conductive semiconductor layer 153, active layer 154, and second conductive semiconductor layer 155 form a stack structure as shown in FIG. 5A.

In this case, the first conductive semiconductor layer 153 can be a p-type semiconductor layer, and the second conductive semiconductor layer 155 can be an n-type semiconductor layer. However, the present disclosure is not necessarily limited to this, and the first conductive type can be n-type and the second conductive type can be p-type.

Moreover, although this example embodiment is illustrated by assuming the presence of the active layer, the active layer can be omitted if necessary, as stated above. In an example, the p-type semiconductor layer can be P-type GaN doped with Mg, and the n-type semiconductor layer can be N-type GaN doped with Si on the n electrode.

The growth substrate 159 (e.g., a wafer) can be formed of, but not limited to, light-transmissive material—for example, at least one among sapphire (Al₂O₃), GaN, ZnO, and AlO. Also, the growth substrate 159 can be made from a material suitable for growing semiconductor materials or carrier wafer. The growth substrate 159 can be formed of high thermal conducting material, and can be a conductive substrate or insulating substrate—for example, at least one among SiC, Si, GaAs, GaP, InP, and Ga₂O₃ substrates which have higher thermal conductivity than sapphire (Al₂O₃) substrates.

Next, a plurality of semiconductor light-emitting diodes are formed by removing at least part of the first conductive semiconductor layer 153, active layer 154, and second conductive semiconductor layer 155 (see FIG. 5B).

More specifically, isolation is performed so that the light-emitting diodes form a light-emitting diode array. That is, a plurality of semiconductor light-emitting diodes are formed by vertically etching the first conductive semiconductor layer 153, active layer 154, and second conductive semiconductor layer 155, for example.

In the case of horizontal semiconductor light-emitting diodes, a mesa process can be performed which exposes the first conductive semiconductor layer 153 to the outside by vertically removing part of the active layer 154 and second conductive layer 155, and then isolation can be performed which forms an array of semiconductor light-emitting diodes by etching the first conductive semiconductor layer 153.

Next, a second conductive electrode 156 (or p-type electrode) is formed on one surface of the second conductive semiconductor layer 155 (see FIG. 5C). The second conductive electrode 156 can be formed by a deposition method such as sputtering, but the present disclosure is not necessarily limited to this. In a case where the first conductive semiconductor layer and the second conductive semiconductor layer are an n-type semiconductor layer and a p-type semiconductor layer, respectively, the second conductive electrode 156 can serve as an n-type electrode.

Next, the growth substrate 159 is removed, thus leaving a plurality of semiconductor light-emitting diodes. For example, the growth substrate 159 can be removed using laser lift-off (LLO) or chemical lift-off (CLO) (see FIG. 5D).

Afterwards, the step of mounting the semiconductor light-emitting didoes 150 on a substrate in a chamber filled with a fluid is performed (see FIG. 5E).

For example, the semiconductor light-emitting diodes 150 and the substrate are put into the chamber filled with a fluid, and the semiconductor light-emitting diodes are self-assembled onto the substrate 161 using fluidity, gravity, surface tension, etc. In this case, the substrate can be an assembly substrate 161.

In another example, a wiring substrate, instead of the assembly substrate 161, can be put into an assembly chamber, and the semiconductor light-emitting diodes 150 can be mounted directly onto the wiring substrate. In this case, the substrate can be a wiring substrate. For convenience of explanation, the present disclosure is illustrated with an example in which the semiconductor light-emitting diodes 150 are mounted onto the assembly substrate 161.

To facilitate the mounting of the semiconductor light-emitting diodes 150 onto the assembly substrate 161, cells into which the semiconductor light-emitting diodes 150 are fitted can be provided on the assembly substrate 161. Specifically, cells where the semiconductor light-emitting diodes 150 are mounted are formed on the assembly substrate 161, at positions where the semiconductor light-emitting diodes 150 are aligned with wiring electrodes. The semiconductor light-emitting diodes 150 are assembled to the cells as they move within the fluid.

After arraying the semiconductor light-emitting didoes on the assembly substrate 161, the semiconductor light-emitting diodes can be transferred to the wiring substrate from the assembly substrate 161, thereby enabling a large-area transfer across a large area. Thus, the assembly substrate 161 can be referred to as a temporary substrate.

Meanwhile, the above-described self-assembly method requires a higher transfer yield so that it can be applied to the manufacture of large-screen displays. The present disclosure proposes a method and device that minimizes the effects of gravity or friction and avoids non-specific binding, in order to increase the transfer yield.

In this case, in the display device according to the present disclosure, a magnetic material is placed on the semiconductor light-emitting diodes so that the semiconductor light-emitting diodes are moved by magnetic force, and the semiconductor light-emitting diodes are mounted at preset positions by an electric field while in the process of being moved. This transfer method and device will be described in more details below with reference to the accompanying drawings.

FIG. 6 is a conceptual diagram showing an example of a device for self-assembling semiconductor light-emitting diodes according to the present disclosure. FIG. 7 is a block diagram of the self-assembly device of FIG. 6. FIGS. 8A to 8E are conceptual diagrams showing a process for self-assembling semiconductor light-emitting diodes using the self-assembly device of FIG. 6. FIG. 9 is a conceptual diagram for explaining the semiconductor light-emitting diodes of FIGS. 8A to 8E.

Referring to FIGS. 6 and 7, the self-assembly device 160 of the present disclosure can comprise an assembly chamber 162, magnets 163, and a position controller 164.

The assembly chamber 162 is equipped with space for a plurality of semiconductor light-emitting diodes. The space can be filled with a fluid, and the fluid can be an assembly solution, which includes water or the like. Thus, the assembly chamber 162 can be a water tank and configured as open-type. However, the present disclosure is not limited to this, and the assembly chamber 162 can be a closed-type chamber that comes with a closed space.

A substrate 161 can be placed in the assembly chamber 162 so that an assembly surface where the semiconductor light-emitting diodes 150 are assembled facing downwards. For example, the substrate 161 is fed to an assembly site by a feed unit, and the feed unit can come with a stage 165 where the substrate is mounted. The position of the stage 165 can be adjusted by the controller, whereby the substrate 161 can be fed to the assembly site.

In this instance, the assembly surface of the substrate 161 at the assembly site faces the bottom of the assembly chamber 162. As shown in the drawings, the assembly surface of the substrate 161 is placed in such a way as to be soaked with the fluid in the assembly chamber 162. Thus, the semiconductor light-emitting diodes 150 in the fluid are moved to the assembly surface.

The substrate 161 is an assembly substrate where an electric field can be formed, and can comprise a base portion 161 a, a dielectric layer 161 b, and a plurality of electrodes 161 c.

The base portion 161 a is made of insulating material, and the electrodes 161 c can be thin-film or thick-film bi-planar electrodes that are patterned on one surface of the base portion 161 a. The electrodes 161 c can be formed of a stack of Ti/Cu/Ti, Ag paste, ITO, etc.

The dielectric layer 161 b can be made of inorganic material such as SiO₂, SiNx, SiON, Al₂O₃, TiO₂, HfO₂, etc. Alternatively, the dielectric layer 161 b can be an organic insulator and composed of a single layer or multi-layers. The thickness of the dielectric layer 161 b can range from several tens of nm to several μm.

Further, the substrate 161 according to the present disclosure comprises a plurality of cells 161 d that are separated by partition walls 161 e. The cells 161 d can be sequentially arranged in one direction and made of polymer material. Also, the partition walls 161 e forming the cells 161 d can be shared with neighboring cells 161 d. The partition walls 161 e can protrude from the base portion 161 a, and the cells 161 d can be sequentially arranged in one direction along the partition walls 161 e. More specifically, the cells 161 d can be sequentially arranged in column and row directions and have a matrix structure.

As shown in the drawings, the cells 161 d can have recesses for accommodating the semiconductor light-emitting diodes 150, and the recesses can be spaces defined by the partition walls 161 e. The recesses can have a shape identical or similar to the shape of the semiconductor light-emitting diodes. For example, if the semiconductor light-emitting diodes are rectangular, the recesses can be rectangular too. Moreover, the recesses formed in the cells can be circular if the semiconductor light-emitting diodes are circular. Further, each cell is configured to accommodate one semiconductor light-emitting diode. That is, one cell accommodates one semiconductor light-emitting diode.

Meanwhile, the plurality of electrodes 161 c have a plurality of electrode lines that are placed at the bottom of the cells 161 d, and the electrode lines can be configured to extend to neighboring cells.

The electrodes 161 c are placed on the undersides of the cells 161 d, and different polarities can be applied to create an electric field within the cells 161 d. To form an electric field, the dielectric layer 161 b can form the bottom of the cells 161 d while covering the electrodes 161 c. With this structure, when different polarities are applied to a pair of electrodes 161 c on the underside of each cell 161 d, an electric field is formed and the semiconductor light-emitting diodes can be inserted into the cells 161 d by the electric field.

The electrodes of the substrate 161 at the assembly site are electrically connected to a power supply 171. The power supply 171 performs the function of generating an electric field by applying power to the electrodes.

As shown in the drawings, the self-assembly device can have magnets 163 for applying magnetic force to the semiconductor light-emitting diodes. The magnets 163 are placed at a distance from the assembly chamber 162 and apply a magnetic force to the semiconductor light-emitting diodes 150. The magnets 163 can be placed to face the opposite side of the assembly surface of the substrate 161, and the positions of the magnets 163 are controlled by the position controller 164 connected to the magnets 163.

The semiconductor light-emitting diodes 1050 can have a magnetic material so that they are moved within the fluid by a magnetic field.

Referring to FIG. 9, a semiconductor light-emitting diode having a magnetic material can comprise a first conductive electrode 1052, a second conductive electrode 1056, a first conductive semiconductor layer 1053 where the first conductive electrode 1052 is placed, a second conductive semiconductor layer 1055 which overlaps the first conductive semiconductor layer 1053 and where the second conductive semiconductor layer 1055 is placed, and an active layer 1054 placed between the first and second conductive semiconductor layers 1053 and 1055.

Here, the first conductive can refer to p-type, and the second conductive type can refer to n-type, or vice versa. As stated previously, the semiconductor light-emitting diode can be formed without the active layer.

Meanwhile, in the present disclosure, the first conductive electrode 1052 can be formed after the semiconductor light-emitting diode is assembled onto the wiring substrate by the self-assembling of the semiconductor light-emitting diode. Further, in the present disclosure, the second conductive electrode 1056 can comprise a magnetic material. The magnetic material can refer a magnetic metal. The magnetic material can be Ni, SmCo, etc. In another example, the magnetic material can include at least one among Gd-based, La-based, and Mn-based materials.

The magnetic material can be provided in the form of particles on the second conductive electrode 1056. Alternatively, one layer of a conductive electrode comprising a magnetic material can be composed of the magnetic material. An example of this is the second conductive electrode 1056 of the semiconductor light-emitting diode 1050 which comprises a first layer 1056 a and a second layer 1056 b, as shown in FIG. 9. Here, the first layer 1056 a can comprise a magnetic material, and the second layer 1056 b can comprise a metal material other than the magnetic material.

As shown in the drawing, in this example, the first layer 1056 a comprising the magnetic material can be placed in contact with the second conductive semiconductor layer 1055. In this case, the first layer 1056 a is placed between the second layer 1056 b and the second conductive semiconductor layer 1055. The second layer 1056 b can be a contact metal that is connected to the wiring electrode on the wiring substrate. However, the present disclosure is not necessarily limited to this, and the magnetic material can be placed on one surface of the first conductive semiconductor layer.

Referring again to FIGS. 6 and 7, more specifically, on top of the assembly chamber of the self-assembly device, a magnet handler (or magnetic handler) capable of automatically or manually moving the magnets 163 on the x, y, and z axes or a motor capable of rotating the magnets 163 can be provided. The magnet handler and motor can constitute the position controller 164. As such, the magnets 163 can rotate in a horizontal, clockwise, or counterclockwise direction to the substrate 161.

Meanwhile, the assembly chamber 162 can be formed with a light-transmissive bottom plate 166, and the semiconductor light-emitting diodes can be placed between the bottom plate 166 and the substrate 161. An image sensor 167 can be placed opposite to the bottom plate 166 so as to monitor the inside of the assembly chamber 162 through the bottom plate 166. The image sensor 167 can be controlled by a controller 172, and can come with an inverted-type lens, CCD, etc. so as to observe the assembly surface of the substrate 161.

The above-described self-assembly device is configured to use a magnetic field and an electric field in combination. With this, the semiconductor light-emitting diodes are mounted at preset positions on the substrate by an electric field while in the process of being moved by changes in the positions of the magnets. Below, the assembly process using the above-described self-assembly device will be described in more details.

First of all, a plurality of semiconductor light-emitting diodes 1050 having a magnetic material can be formed through the process explained with reference to FIGS. 5A to 5C. In this case, the magnetic material can be deposited onto the semiconductor light-emitting didoes in the process of forming the second conductive electrode of FIG. 5C.

Next, the substrate 161 is fed to an assembly site, and the semiconductor light-emitting diodes 1050 are put into the assembly chamber 162 (see FIG. 8A).

As described above, the assembly site on the substrate 161 can be a position at which the substrate 161 is placed in the assembly chamber 162 in such a way that an assembly surface where the semiconductor light-emitting diodes 150 are assembled faces downwards.

In this case, some of the semiconductor light-emitting diodes 1050 can sink to the bottom of the assembly chamber 162 and some of them can float in the fluid. If the assembly chamber 162 comes with a light-transmissive bottom plate 166, some of the semiconductor light-emitting diodes 1050 can sink to the bottom plate 166.

Next, a magnetic force is applied to the semiconductor light-emitting diodes 1050 so that the semiconductor light-emitting diodes 1050 in the assembly chamber 162 come up to the surface (see FIG. 8B).

When the magnets 163 of the self-assembly device move to the opposite side of the assembly surface of the substrate 161 from their original positions, the semiconductor light-emitting diodes 1050 float in the fluid towards the substrate 161. The original positions can refer to positions at which the magnets 163 are outside the assembly chamber 162. In another example, the magnets 163 can be composed of electromagnets. In this case, an initial magnetic force is generated by supplying electricity to the electromagnets.

Meanwhile, in this embodiment, the assembly surface of the substrate 161 and the spacing between the semiconductor light-emitting diodes 1050 can be controlled by adjusting the strength of the magnetic force. For example, the spacing is controlled by using the weight, buoyancy, and magnetic force of the semiconductor light-emitting diodes 1050. The spacing can be several millimeters to several tens of micrometers from the outermost part of the substrate 161.

Next, a magnetic force is applied to the semiconductor light-emitting diodes 1050 so that the semiconductor light-emitting diodes 1050 move in one direction within the assembly chamber 162. For example, the magnets 163 can move in a horizontal, clockwise, or counterclockwise direction to the substrate 161 (see FIG. 8C). In this case, the semiconductor light-emitting diodes 1050 are moved horizontally to the substrate 161 by the magnetic force, spaced apart from the substrate 161.

Next, the semiconductor light-emitting diodes 1050 are guided to preset positions on the substrate 161 by applying an electric field so that the semiconductor light-emitting diodes 1050 are mounted at the preset positions while in the process of being moved (see FIG. 8C). For example, the semiconductor light-emitting diodes 1050 are moved vertically to the substrate 161 by the electric field and mounted at preset positions on the substrate 161, while being moved horizontally to the substrate 161.

More specifically, an electric field is generated by supplying power to bi-planar electrodes on the substrate 161, and the semiconductor light-emitting diodes 1050 are guided to the preset positions and assembled only there by the electric field. That is, the semiconductor light-emitting diodes 1050 are self-assembled at an assembly site on the substrate 161 by a selectively generated electric field. To this end, the substrate 161 can be formed with cells into which the semiconductor light-emitting diodes 1050 are fitted.

Afterwards, the unloading of the substrate 161 is performed, thereby completing the assembly process. In a case where the substrate 161 is an assembly substrate, an array of semiconductor light-emitting diodes can be transferred onto a wiring substrate to carry out a subsequent process for realizing the display device, as described previously.

Meanwhile, after the semiconductor light-emitting diodes 1050 are guided to the preset positions, the magnets 163 can be moved in a direction in which they get farther away from the substrate 161, so that the semiconductor light-emitting diodes 1050 remaining in the assembly chamber 162 fall to the bottom of the assembly chamber 162 (see FIG. 8D). In another example, if power supply is stopped in a case where the magnets 163 are electromagnets, the semiconductor light-emitting diodes 1050 remaining in the assembly chamber 162 fall to the bottom of the assembly chamber 162.

Thereafter, the semiconductor light-emitting diodes 1050 on the bottom of the assembly chamber 162 can be collected, and the collected semiconductor light-emitting diodes 1050 can be re-used.

In the above-described self-assembly device and method, parts distant from one another are concentrated near a preset assembly site by using a magnetic field in order to increase assembly yields in a fluidic assembly, and the parts are selectively assembled only at the assembly site by applying an electric field to the assembly site. In this case, the assembly substrate is positioned on top of a water tank, with its assembly surface facing downward, thus minimizing the effect of gravity from the weights of the parts and avoiding non-specific binding and eliminating defects.

As seen from above, with the above configuration according to the present disclosure, large numbers of semiconductor light-emitting diodes can be assembled at a time on a display device where individual pixels are made up of semiconductor light-emitting diodes.

As such, according to the present disclosure, large numbers of semiconductor light-emitting diodes can be pixelated on a small-sized wafer and then transferred onto a large-area substrate. This enables the manufacture of a large-area display device at a low cost.

When the self-assembly process described above is performed, several problems occur.

Firstly, as an area of the display increases, an area of the assembly substrate increases. As the area of the assembly substrate increases, there is a problem that a warpage phenomenon of the assembly substrate increases due to a weight of the assembly substrate. When a self-assembly is performed in a state in which the assembly substrate is warped, since the magnetic field at the surface of the assembly substrate is not uniformly formed, it is difficult to perform the self-assembly stably.

Secondly, since the semiconductor light-emitting diodes may not be completely uniformly dispersed in the fluid and the magnetic field formed at the surface of the assembly substrate may not be uniform completely, a problem that the semiconductor light-emitting diodes are concentrated only at a partial region of the assembly substrate can occur.

The present disclosure provides a self-assembly device capable of solving the above-described problems and increasing a self-assembly yield.

The self-assembly device according to the present disclosure can include a substrate surface treatment part, a substrate chuck 200, a magnetic field forming part 300, a chip supply part 400, and an assembly chamber 500. However, the present disclosure is not limited thereto, and the self-assembly device according to the present disclosure can include more or less components than those described above.

Prior to describing the self-assembly device according to the present disclosure, a method for self-assembly using the self-assembly device according to the present disclosure will be described briefly.

FIG. 10 is a flowchart showing a method for self-assembly according to the present disclosure.

First, a surface treatment step S110 of an assembly substrate is performed. The step is not essential, but when a surface of the substrate is hydrophilized, it is possible to prevent bubbles from being generated on the surface of the substrate.

Next, a step S120 of loading the assembly substrate onto the substrate chuck is performed. The assembly substrate loaded on the substrate chuck 200 is transferred to an assembly position of the assembly chamber. Thereafter, the magnetic field forming part approaches the assembly substrate through vertical and horizontal movements.

In such a state, a step S130 of supplying a chip is performed. Specifically, a step of dispersing the semiconductor light-emitting diode on the assembly surface of the assembly substrate is performed. When the semiconductor light-emitting diode is dispersed near the assembly surface in a state in which the magnetic field forming part 300 is close enough to the assembly substrate, the semiconductor light-emitting diodes adhere to the assembly surface by the magnetic field forming part. The semiconductor light-emitting diodes are dispersed onto the assembly surface at an appropriate dispersion.

However, the present disclosure is not limited thereto, and the semiconductor light-emitting diode can be dispersed into the fluid in the assembly chamber before the substrate is transferred to the assembly position. That is, a time point at which the chip supply step S130 is performed is not limited to after the assembly substrate is transferred to the assembly position.

A method of supplying the semiconductor light-emitting diode can vary according to an area of the assembly substrate, a type of the semiconductor light-emitting diode to be assembled, and a self-assembly speed.

Thereafter, a step S140 of performing the self-assembly and collecting the semiconductor light-emitting diode is performed. The self-assembly will be described later together with a description of a self-assembly device according to the present disclosure. Meanwhile, the semiconductor light-emitting diode is not necessarily collected after the self-assembly. After the self-assembly is completed, the semiconductor light-emitting diode in the assembly chamber is replenished, and then a new substrate can be self-assemble the semiconductor light-emitting diode.

Lastly, after the self-assembly is completed, a step S150 of inspecting and drying the assembly substrate, and separating the substrate from the substrate chuck can be performed. The inspection of the assembly substrate can be performed at the position in which the self-assembly has been performed, and can be performed after the assembly substrate is transferred to another position.

Meanwhile, the drying of the assembly substrate can be performed after the assembly substrate is separated from the fluid. After the drying of the assembly substrate, a post process of the self-assembly can be performed.

Contents of a basic principle of the self-assembly, a structure of the substrate (or assembly substrate), and the semiconductor light-emitting diode are replaced with those described in FIGS. 1 to 9. Meanwhile, since a vertical moving part, a horizontal moving part, a rotating part, and other moving means described below can be implemented through several known means such as a motor and a ball screw, a rack gear and a pinion gear, and a pulley and a timing belt, and the like, detailed descriptions thereof will be omitted.

Meanwhile, the controller 172 described in FIG. 7 controls movements of the vertical moving part, the horizontal moving part, the rotating part, and other moving means provided in the above-described components. That is, the controller 172 is configured to control movements of x, y, and z axes and a rotating movement of each component. Even though not mentioned separately in the specification, the movements of the vertical moving part, the horizontal moving part, the rotating part, and other moving means are generated by the control of the controller 172.

Meanwhile, the electrode 161 c provided at the substrate (or assembly substrate 161) described in FIGS. 6 to 9 is referred to as an assembly electrode, the assembly electrode 161 c is electrically connected to the power supply 171 described in FIG. 7 via the substrate chuck 200, and the power supply 171 supplies power to the assembly electrode 161 c by the control of the controller 172. Detailed description thereof will be described later.

Hereinafter, the above-described components will be described.

First, a substrate surface treatment part serves to hydrophilize a substrate surface. Specifically, the self-assembly device according to the present disclosure performs a self-assembly in a state in which the assembly substrate is in contact with a fluid surface. When the assembly surface of the assembly substrate has a heterogeneous property with the fluid surface, bubbles and the like can occur at the assembly surface, and non-specific coupling between the semiconductor light-emitting diode and the assembly surface can occur. To prevent this, the substrate surface can be treated with fluid-friendly properties before the self-assembly.

In one embodiment, when the fluid is a polar material such as water, the substrate surface treatment part can hydrophilize the assembly surface of the substrate.

For example, the substrate surface treatment part can include a plasma generator. Hydrophilic functional groups can be formed at the substrate surface by plasma treatment of the substrate surface. Specifically, the hydrophilic functional groups can be formed at at least one of a partition wall and a dielectric layer provided at the substrate by the plasma treatment.

Meanwhile, different surface treatments can be performed at a partition wall surface and a surface of the dielectric layer exposed to the outside by a cell so as to prevent non-specific coupling of the semiconductor light-emitting diode. For example, a hydrophilic treatment can be performed at the surface of the dielectric layer exposed to the outside by the cell, and a surface treatment can be performed to form hydrophobic functional groups at the surface of the partition wall. Accordingly, non-specific coupling of the semiconductor light-emitting diode with respect to the surface of the partition wall can be prevented, and the semiconductor light-emitting diode can be strongly fixed inside the cell.

However, the substrate surface treatment part is not an essential component in the self-assembly device according to the present disclosure. The substrate surface treatment part may not be necessary depending on a material configuring the substrate.

The substrate at which the surface treatment is completed by the substrate surface treatment part is loaded onto a substrate chuck 200.

Next, the substrate chuck 200 will be described.

FIG. 11 is a conceptual diagram showing a first state of a substrate chuck, FIG. 12 is a conceptual diagram showing a second state of the substrate chuck, FIG. 13 is a plan view of a first frame provided at the substrate chuck, and FIG. 14 is a conceptual diagram showing a state in which an assembly substrate is loaded at the substrate chuck.

Referring to the accompanying drawings, the substrate chuck 200 includes a substrate support part (or substrate support) 205. In one embodiment, the substrate support part 205 can include includes first and second frames 210 and 220 and a fixing part 230. The first and second frames 210 and 220 are disposed at upper and lower sides of the loaded substrate interposed therebetween, and the fixing part 230 supports the first and second frames 210 and 220. The substrate chuck 200 can include all of a rotating part 240 (or a rotator), a vertical moving part (or a vertical mover), and a horizontal moving part (or a horizontal mover). As shown in FIG. 11, the vertical moving part and the horizontal moving part can be formed as one device as a moving part 250, but such is not required, and the vertical moving part and the horizontal moving part may can be formed separately. Meanwhile, the present disclosure is not limited to drawings described below, and the rotating part, the vertical and horizontal moving parts provided at the substrate chuck can be formed as one device.

In the present specification, the first frame 210 is defined as a frame disposed at a lower side of the substrate in a state in which the assembly surface of the substrate S faces a fluid, and the second frame 220 is defined as a frame disposed at a upper side of the substrate in a state in which the assembly surface of the substrate faces the fluid. The upper and lower sides relation between the first frame 210 and the second frame 220 can be switched with each other due to the rotating part 240. In the present specification, a state in which the first frame 210 is under the second frame 220 is defined as a first state (see FIG. 11), and a state in which the first frame 210 is over the second frame 220 is defined as a second state (see FIG. 12). The rotating part 240 rotates at least one of the first and second frames 210 and 220 and the fixing part 230 to switch from any one of the first and second states to the other. The rotating part 240 will be described later.

The first frame 210 is a frame in contact with the fluid filled in the assembly chamber during self-assembly. Referring to FIG. 14, the first frame 210 includes a bottom portion 210′ and a sidewall portion 210″.

The bottom portion 210′ serves to support the substrate at the lower side or the upper side of the substrate S when the substrate S is loaded. The bottom portion 210′ can be formed in one plate shape, or can be formed in a form in which a plurality of members forming a plate shape are coupled to each other. Referring to FIG. 13, the bottom portion 210′ includes a hole 210′″ passing through a central portion. The hole 210′″ can expose a substrate which will be described later to the outside to be in contact with the fluid. That is, the hole 210′″ defines the assembly surface of the substrate. The substrate is loaded such that four corners of the rectangular substrate are mounted on an edge of the hole 210′″ of the first frame 210. Accordingly, a remaining region except the edge of the substrate is overlapped with the hole 210′″ provided at the first frame 210. The region of the substrate overlapped with the hole 210′″ becomes an assembly surface. Buoyancy (or upthrust), is a force (e.g., upward) exerted by a fluid that opposes the weight of an immersed object, such as the substrate support part 205. In this context, the hole 210′″ is an area of the first frame 210 (e.g., of the bottom portion 210′) that does not directly support a surface of the substrate S. Accordingly, when the substrate support part 205 is placed on or partially immersed in the fluid, a force is applied (e.g., by the fluid due to pressure difference between air on one side and the fluid on another side of the substrate S) to a portion of the substrate S that is over the hole 210′″, the substrate S becomes pushed (or pulled) so that the substrate S goes from a curved state under its own weight (without support or buoyancy from the fluid) to a flat state (or oppositely curved state) due to support or due to a counterforce to the weight from buoyancy or pressure that is difference from that of the fluid.

Meanwhile, a sealing part 212 and an electrode connection part 213 can be disposed at or adjacent the edge of the hole 210′″, and can be arranged parallel to the edge of the hole 210′″.

The sealing part 212 is in close contact with the substrate to prevent the fluid filled in the assembly chamber from penetrating into the first and second frames 210 and 220 during self-assembly. In addition, the sealing part 212 prevents the fluid from penetrating into the assembly electrode 161 c and the electrode connection part 213. For this, the sealing part 212 should be disposed at a position closer to the hole 210′″ than the electrode connection part 213.

The sealing part 212 is formed in a ring shape, and a material of the sealing part 212 is not particularly limited. The material forming the sealing part 212 can be a known sealing material.

The electrode connection part 213 is connected to the assembly electrode formed at the substrate to supply a power to the assembly electrode. In one embodiment, the electrode connection part 213 can apply a power supplied from the power supply 171 described in FIG. 7 to the assembly electrode 161 c to form an electric field on the substrate.

Meanwhile, the sidewall portion 210″ is formed at an edge of the bottom portion 210′. The sidewall portion 210″ prevents the fluid from penetrating into an opposite surface of the assembly surface of the substrate during self-assembly. Specifically, the self-assembly device according to the present disclosure performs self-assembly in a state in which the substrate is submerged in the fluid. The sidewall portion 210″ prevents the fluid from penetrating into the opposite surface of the assembly surface of the substrate when the substrate is submerged in the fluid.

For this, the sidewall portion 210″ is formed to surround an entire edge of the substrate. A height of the sidewall portion 210″ should be greater than a depth at which the substrate is submerged in the fluid. The sidewall portion 210″ prevents the fluid from penetrating into the opposite surface of the assembly surface of the substrate, and thus the substrate is prevented from being damaged, and buoyancy of the fluid is applied to only one surface of the substrate. This will be described later.

Meanwhile, the second frame 220 serves to press the substrate at the opposite side of the first frame 210 during self-assembly. Like the first frame 210, the second frame 220 includes a hole passing through a central portion. The hole formed at the second frame 220 is formed to have a size equal to or larger than the hole 210′″ formed at the first frame 210.

The hole formed at the second frame 220 allows the opposite surface of the assembly surface of the substrate to be exposed to the outside. The opposite surface of the assembly surface of the substrate should be exposed to the outside in the same area as the assembly surface or in a larger area than the assembly surface. This is because the magnetic field forming part 300 forms a magnetic field at the opposite side of the assembly surface of the substrate. The opposite surface of the assembly surface of the substrate should be exposed to the outside such that the magnetic field forming part 300 can sufficiently approach the substrate.

Meanwhile, the substrate S is loaded between the first and second frames 210 and 220 in the second state. Accordingly, the substrate S is slid and loaded at one surface of the second frame 220. A protrusion for guiding an alignment position of the substrate can be formed at at least one of the first and second frames such that the substrate is aligned to a correct position. In one embodiment, referring to FIG. 13, a protrusion 211 guiding the alignment position of the substrate S can be formed at the first frame 210.

Meanwhile, when the substrate S is loaded on the second frame 220, at least one of the first and second frames 210 and 220 moves vertically such that the first and second frames 210 and 220 press the substrate. For this, the substrate chuck 200 can include a frame moving part disposed at at least one of the fixing part 230, and the first and the second frames 210 and 220. At this time, the sealing part 212 presses the substrate S.

In one embodiment, a frame moving part for vertically moving the second frame 220 can be disposed at the fixing part 230. While the substrate chuck is in the second state, when the substrate S is loaded on the second frame 220, the vertical moving part moves the second frame 220 upwardly such that the substrate S can be strongly fixed between the first and second frames 210 and 220. At this time, the electrode connection part 213 provided at the first frame 210 is connected to the assembly electrode of the substrate S, and the sealing part 212 provided at the first frame 210 presses the edge of the substrate S. In this state, when the substrate chuck switches to the first state, the substrate chuck has a shape as shown in FIG. 14.

However, the present disclosure is not limited thereto, and the frame moving part can be formed so as to move any one of the first and second frames 210 and 220 horizontally with respect to the other. In this case, the frame moving part is formed so as to move any one of the first and second frames 210 and 220 vertically and horizontally with respect to the other. When any one of the first and second frames 210 and 220 can be moved horizontally with respect to the other, a connection part between the electrode connection part 213 and the assembly electrode can be changed. It can be used to detect whether the assembled electrode is defective.

Meanwhile, the rotating part 240 is disposed at one side of the fixing part 230 provided at the substrate chuck 200 described above. The rotating part 240 rotates the fixing part 230 such that the upper and lower-sides relation of the first and second frames 210 and 220 can be switched to each other. The substrate chuck 200 is switched from any one of the first and second states to the other by rotating movement of the rotating part 240. A rotation speed, a degree of rotation, a rotation direction, and the like of the rotating part 240 can be controlled by the controller 172 described in FIG. 7.

In one embodiment, the substrate chuck 200 is in the second state before the substrate S is loaded, and the controller 172 controls the rotating part 240 to rotate the fixing part 230 to 180 degrees after the substrate S is loaded such that the substrate chuck 200 is switched to the first state.

Meanwhile, a vertical moving part and a horizontal moving part are disposed at one side of the fixing part 230.

The horizontal moving part moves at least one of the fixing part 230, and the first and second frames 210 and 220 such that the assembly surface of the substrate can be aligned at an open position of the assembly chamber after the substrate is loaded.

The vertical moving part moves at least one of the fixing part 230, and the first and second frames 210 and 220 such that the vertical distance between the substrate and the assembly chamber is adjusted. A warpage phenomenon of the substrate S can be corrected or compensated by the vertical moving part using the buoyancy. This will be described later.

In summary, the substrate S is loaded in the second state of the substrate chuck 200 (see FIG. 12). Thereafter, the substrate chuck 200 is switched to the first state (see FIG. 11) and then aligned with the assembly chamber. In this process, the substrate chuck 200 moves vertically and horizontally such that the assembly surface of the substrate S is in contact with the fluid filled in the assembly chamber. Thereafter, the controller 172 controls the magnetic field forming part 300.

Next, the magnetic field forming part 300 will be described.

FIG. 15 is a perspective view of a magnetic field forming part according to one embodiment of the present disclosure, FIG. 16 is one side view of a magnetic field forming part according to one embodiment of the present disclosure, FIG. 17 is a bottom side view of a magnetic field forming part according to one embodiment of the present disclosure, and FIG. 18 is a conceptual diagram showing a trajectory of magnets provided at a magnetic field forming part according to the present disclosure.

Referring to the drawings, the magnetic field forming part 300 includes a magnet array 310, a vertical moving part 320, a horizontal moving part 320, and a rotating part 320. The magnetic field forming part 300 is disposed at an upper side of the assembly electrode to serve to form a magnetic field.

Specifically, the magnet array 310 includes a plurality of magnets 313. The magnet 313 provided at the magnet array 310 can be a permanent magnet or an electromagnet. The magnets 313 serves to form a magnetic field so that the semiconductor light-emitting diodes are led to the assembly surface of the substrate.

The magnet array 310 can include a support part 311 and a magnet moving part 312. The support part 311 is connected to the parts 320 that can include a vertical moving part, a horizontal moving part, and a rotating part.

Meanwhile, one end of the magnet moving part 312 is fixed to the support part 311, and the magnet 313 is fixed to the other end of the magnet moving part 312. The magnet moving part 312 is formed to be stretchable in length, and as the magnet moving part 312 is stretched, a distance between the magnet 313 and the support part 311 changes.

As shown in the accompanying drawings, the magnet moving part 312 can be configured to vertically move the magnets 313 disposed in one row at a time. In this case, the magnet moving part 312 can be disposed for each column of the magnet array.

On the other hand, the magnet moving part 312 can be disposed by the number of magnets provided in the magnet array. Accordingly, a distance between each of a plurality of magnets and the support part can be adjusted differently.

The plurality of magnet moving parts serves to adjust finely a gap between the magnet 313 and the substrate S, and when the substrate is warped, serves to adjust uniformly the gaps between the magnets 313 and the substrate S. Self-assembly can be performed in a state in which the magnet 313 is in contact with the substrate S, or can be performed in a state in which the magnet 313 is spaced apart from the substrate S at a predetermined distance.

Meanwhile, the horizontal moving part can include a rotating part. When the self-assembly is performed, the horizontal moving part provided at the magnetic field forming part 300 moves the magnet in one direction and rotates the magnet, simultaneously. Accordingly, the magnet array 310 rotates with respect to a predetermined rotation axis and moves along one direction, simultaneously. For example, referring to FIG. 18, the magnet 313 provided at the magnet array 310 can move while drawing a trajectory P mixed with a curved line and a straight line.

The semiconductor light-emitting diode can be supplied in a state in which the magnetic field forming part 300 is close to the substrate S within a predetermined distance.

FIG. 19 is a conceptual diagram showing a state in which a semiconductor light-emitting diode is supplied.

Referring to FIG. 19, a chip supply part 400 can be disposed in an assembly chamber 500 to be described later. The substrate S is aligned with the assembly chamber 500, and then the chip supply part 400 serves to supply the semiconductor light-emitting diode to the assembly surface of the substrate S. Specifically, the chip supply part 400 can include a chip accommodating part that can accommodate a chip at an upper portion thereof, a vertical moving part, and a horizontal moving part. The vertical and horizontal moving parts allow the chip accommodating part to move in the fluid filled in the assembly chamber.

The plurality of semiconductor light-emitting diodes can be loaded at the chip accommodating part. After the substrate is aligned with the assembly chamber, when the magnetic field forming part 300 is brought close to the substrate within a predetermined distance, a magnetic field of a predetermined intensity or more is formed on the assembly surface. In this state, when the chip accommodating part is brought close to the assembly surface within the predetermined distance, the semiconductor light-emitting diodes loaded at the chip accommodating part are in contact with the substrate. The vertical moving part provided at the chip supply part brings the chip accommodating part close to a partial region of the assembly surface of the substrate within the predetermined distance through vertical movement.

After a predetermined time passes, the vertical moving part provided at the chip supply part allows the chip accommodating part to be separated from the partial region of the assembly surface of the substrate at the predetermined distance or longer through vertical movement. Thereafter, the horizontal moving part provided at the chip supply part moves horizontally the chip accommodating part such that the chip accommodating part is overlapped with a different region from the partial region of the assembly surface. Thereafter, the vertical moving part provided at the chip supply part brings the chip accommodating part close to the different region within the predetermined distance through vertical movement. By repeating such a process, the chip supply part brings the plurality of semiconductor light-emitting diodes into contact with an entire region of the assembly surface of the substrate. Self-assembly can be performed in a state in which the plurality of semiconductor light-emitting diodes are constantly dispersed and in contact with the entire region of the assembly surface of the substrate.

As described above, there are largely two problems in self-assembly. A second problem is that since the semiconductor light-emitting diodes may not be completely uniformly dispersed in the fluid and the magnetic field formed at the surface of the assembly substrate may not be perfectly uniform, there is a problem that the semiconductor light-emitting diodes are concentrated only at a partial region of the assembly substrate. When using the chip supply part 400 described above, it is possible to solve the second problem described above.

However, the present disclosure is not limited thereto, and the chip supply part is not an essential component of the present disclosure. Self-assembly can be performed in a state in which the semiconductor light-emitting diode is dispersed in the fluid, or in a state in which the plurality of semiconductor light-emitting diodes are dispersed and in contact with the assembly surface of the substrate by another part which is not the chip supply part.

Next, the assembly chamber 500 will be described.

FIG. 20 is a plan view of an assembly chamber according to one embodiment of the present disclosure, FIG. 21 is a cross-sectional view taken along line A-A′ of FIG. 20, and FIGS. 22 and 23 are conceptual diagrams showing a movement of a gate provided at an assembly chamber according to one embodiment of the present disclosure.

The assembly chamber 500 includes a space for accommodating a plurality of semiconductor light-emitting diodes. The space can be filled with a fluid, and the fluid can include water, and the like as an assembly solution. Therefore, the assembly chamber 500 can be a water tank, and can be configured as an open type. However, the present disclosure is not limited thereto, and the space of the assembly chamber 500 can be a closed type formed in a closed space.

In the assembly chamber 500, a substrate S is disposed such that an assembly surface at which the semiconductor light-emitting diodes 150 are assembled is faced downwardly. For example, the substrate S is transferred to an assembly position by the substrate chuck 200.

At this time, the assembly surface of the substrate S at the assembly position faces a bottom of the assembly chamber 500. Accordingly, the assembly surface is toward a direction of gravity. The assembly surface of the substrate S is disposed to be submerged in the fluid in the assembly chamber 500.

In one embodiment, the assembly chamber 500 can be divided into two regions. Specifically, the assembly chamber 500 can be divided into an assembly region 510 and an inspection region 520. In the assembly region 510, the semiconductor light-emitting diode disposed in the fluid is assembled to the substrate S in a state in which the substrate S is submerged in the fluid.

On the other hand, in the inspection region 520, the substrate S that has been self-assembled is inspected. Specifically, the substrate S is assembled at the assembly region and then transferred to the inspection region via the substrate chuck.

The same fluid can be filled in the assembly region 510 and the inspection region 520. The substrate can be transferred from the assembly region to the inspection region in a state in which the substrate is submerged in the fluid. When the substrate S disposed in the assembly region 510 is taken out of the fluid, the previously assembled semiconductor light-emitting diode can be separated from the substrate due to surface energy between the fluid and the semiconductor light-emitting diode. For this reason, it is preferable that the substrate is transferred in a state of being submerged in the fluid.

The assembly chamber 500 can include a gate 530 configured to be capable of moving up and down such that the substrate can be transferred in a state of being submerged in the fluid. As shown in FIG. 22, the gate 530 maintains an elevated state (first state) during self-assembly or during substrate inspection, so that the fluid accommodated in the assembly region 510 and the inspection region 520 of the assembly chamber 500 is separated from each other. The gate 530 separates the assembly region and the inspection region, thereby preventing disturbing the inspection of the substrate due to moving of the semiconductor light-emitting diode to the inspection region during self-assembly.

As shown in FIG. 23, when the substrate S is transferred, the gate 530 moves down (second state) to remove a boundary between the assembly region 510 and the inspection region 520. Accordingly, the substrate chuck 200 can transfer the substrate from the assembly region 510 to the inspection region 520 by only horizontal movement without separate vertical movement.

Meanwhile, a sonic generator for preventing agglomeration of the semiconductor light-emitting diode can be disposed at the assembly region 510. The sonic generator can prevent the plurality of semiconductor light-emitting diodes from agglomerating with each other by vibration.

Meanwhile, bottom surfaces of the assembly region 510 and the inspection region 520 can be made of a light transmissive material. In one embodiment, referring to FIG. 20, light transmission regions 511 and 512 can be provided at the bottom surfaces of the assembly region 510 and the inspection region 520, respectively. Accordingly, the present disclosure enables to monitor the substrate during self-assembly, or to perform inspection with respect to the substrate. It is preferable that an area of the light transmission region is larger than that of the assembly surface of the substrate. However, the present disclosure is not limited thereto, and the assembly chamber can be configured to perform self-assembly and inspection at the same position.

When using the substrate chuck 200, the magnetic field forming part 300, and the assembly chamber 500 as described above, the self-assembly described in FIGS. 8A to 8E can be performed. Hereinafter, a detailed structure and method for solving problems caused during self-assembly will be described in detail.

First, a structure and method for solving the most critical problem that occurs during self-assembly will be described. When describing the problem in detail, as an area of a display increases, an area of an assembly substrate increases, and as the area of the assembly substrate increases, a problem that a warpage phenomenon of the substrate increases occurs. When performing self-assembly in a state in which the assembly substrate is warped, since a magnetic field is not uniformly formed at a surface of the assembly substrate, it is difficult to perform the self-assembly stably.

FIG. 24 is a conceptual diagram showing a substrate warpage phenomenon caused during self-assembly.

Referring to FIG. 24, when a substrate S maintains a flat state during self-assembly, a distance between a plurality of magnets 313 and the substrate S can be uniform. In this case, a magnetic field can be formed uniformly at an assembly surface of the substrate. However, when the substrate is actually loaded onto the substrate chuck 200, the substrate is warped due to gravity. In a warped substrate S′, since a distance between the plurality of magnets 313 and the substrate S′ is not constant, uniform self-assembly is difficult. Since a magnetic field forming part is disposed on an upper side of the substrate, a separate instrument for correcting the warpage phenomenon of the substrate is difficult to be disposed on the upper side of the substrate. In addition, when the separate instrument for correcting the warpage phenomenon of the substrate is disposed on a lower side the substrate, movement of the semiconductor light-emitting diodes can be restricted, and there is a problem that the instrument covers a part of the assembly surface. For this reason, it is difficult to dispose the instrument for correcting the warpage phenomenon of the substrate either on the upper side or the lower side of the substrate.

The present disclosure provides a structure and method of a substrate chuck for correcting a warpage phenomenon of the substrate.

FIG. 25 is a conceptual diagram showing a method for correcting a warpage phenomenon of a substrate.

Referring to FIG. 25, after loading a substrate S′ at a substrate chuck 200, when an assembly surface of the substrate faces the gravity direction, the substrate S′ is warped. In order to minimize warping of the substrate when loading the substrate, at least one of first and second frames 210 and 220 provided at the substrate chuck applies pressure to all four corners of a rectangular substrate. Nevertheless, when the area of the substrate S′ is increased, the substrate is inevitably warped due to gravity.

As shown in the second drawing of FIG. 25, after the substrate chuck 200 is moved to an assembly position, when the substrate chuck 200 is moved down at a predetermined distance, the substrate S′ brings into contact with a fluid F. In a state in which the substrate S′ is simply in contact with the fluid F, the warpage phenomenon of the substrate S′ is not corrected. Although self-assembly can be performed in a state as shown in the second drawing of FIG. 25, it is difficult to perform uniform self-assembly.

The present disclosure further moves down the substrate chuck 200 in the state in which the substrate S′ is in contact with the fluid F in order to correct the warpage phenomenon of the substrate. At this time, a sealing part 212 provided at the first frame 210 prevents the fluid F from penetrating into a window of the first frame. In addition, a sidewall portion 210″ provided at the first frame 210 prevents the fluid F from flowing over the first frame to an opposite surface of the assembly surface of the substrate S′.

Here, the sealing part 212 should be formed to surround all edges of the substrate. In addition, a height of the sidewall portion 210″ should be greater than a depth at which the first frame 210 is moved down to the maximum based on a state in which the first frame 210 is in contact with the fluid F. That is, when the substrate chuck 200 moves down, the fluid should not penetrate over the window and the sidewall portion 210″ of the first frame 210.

When the substrate chuck 200 moves down, a surface of the fluid F is raised due to the sealing part 212 and the sidewall portion 210″ as described above. At this time, buoyancy by the fluid F acts on the substrate S′. As the surface rising width of the fluid F increases, the buoyancy acting on the substrate S′ increases.

In the present disclosure, the buoyancy (and thereby an amount of force) acting on the substrate can be changed by measuring or determining a degree of warping of the substrate S′ and adjusting a descending width of the substrate chuck 200 according to the degree of warping of the substrate. When an appropriate buoyancy is applied to the substrate, as shown in the third drawing of FIG. 25, the substrate S is maintained in a flat state.

The magnetic field forming part 300 is transferred to the upper side of the substrate S in a state in which buoyancy is applied to the substrate S, and then moves horizontally along the substrate S. At this time, power of the power supply 171 is applied to the assembly electrode 161 c via the electrode connection part 213. That is, self-assembly proceeds in a state in which buoyancy is applied to the assembly surface of the substrate S.

According to the above description, it is not necessary to dispose separate structures at the upper and lower sides of the substrate, and the warpage phenomenon of the substrate can be corrected. Accordingly, even when an area of the assembly substrate is increased, the present disclosure enables to achieve a high self-assembly yield.

Meanwhile, the present disclosure allows self-assembly can be performed in a state in which the assembly substrate is almost flat. In addition, the present disclosure minimizes factors that interfere with the self-assembly through control of movement of the substrate chuck, and prevents or avoids the semiconductor light-emitting diode from being separated from the assembly substrate after the self-assembly is completed.

For this, the controller 172 described in FIG. 7 controls the movement of the substrate chuck. Specifically, the controller 172 is configured to control the movement of vertical and horizontal moving parts and a rotating part provided at the substrate chuck 200. Meanwhile, the vertical moving part can be performed not only to move vertically the entire substrate chuck, but also to move vertically at least one of the first and second frames 210 and 220 and the fixing part 230 relative to the other configuration. In the present specification, controlling the substrate chuck by the controller 172 such that the substrate moves vertically can include not only the meaning of vertically moving the entire substrate chuck, but also the meaning of vertically moving at least one of the first and second frames 210 and 220 and the fixing part 230 relative to the other configuration.

For example, controlling substrate chuck by the controller 172 such that the substrate is lowered can include not only the meaning of lowering the entire substrate chuck, but also the meaning of lowering at least one of the first and second frames 210 and 220 and the fixing part 230. Since it can vary depending on a structure of the substrate chuck, the present disclosure is not limited thereto separately.

Hereinafter, a method of controlling the substrate chuck of the controller for applying buoyancy to the substrate described in FIG. 25 will be described in detail.

The controller 172 controls a depth at which the substrate is submerged in the fluid based on a degree of warping of the substrate. For this, the present disclosure further includes a displacement sensor for sensing a degree of warping of the substrate. Specifically, the displacement sensor is configured to sense a distance between the sensor and a measurement target point. The displacement sensor can utilize a known equipment or other equipment, and a detailed description thereof will be omitted.

The displacement sensor 215 can be disposed at any one of the first and second frames 210 and 220 and the fixing part 230 provided in the substrate chuck, and can be configured to change the position thereof by separate moving means. In the embodiment of FIG. 25, the displacement sensor 215 is shown as disposed on the second frame 220.

The displacement sensor senses a vertical distance between one point of the substrate and the displacement sensor on an upper side of the substrate. Specifically, the displacement sensor moves onto one point of the substrate, and then senses a distance between the displacement sensor and the substrate. Thereafter, the displacement sensor moves onto another point of the substrate, and then measures a distance between the another point and the displacement sensor. At this time, the displacement sensor should move horizontally with respect to a reference plane to sense the distance. Since the reference plane on which the displacement sensor moves is fixed, when a distance between each of a plurality of points on the substrate and the displacement sensor is measured, a degree of warping of the substrate can be known or determined.

For example, the displacement sensor disposed on the upper side of the substrate measures a distance from each of an edge and a central portion of the substrate. When the substrate is warped in a direction of gravity, a vertical distance between one point of the edge of the substrate and the displacement sensor is smaller than that between one point of the central portion of the substrate and the displacement sensor.

Meanwhile, a reference height can be set by a user, and the distance measured by the displacement sensor can be converted based on a reference value. For example, the reference value can be defined as a distance between an edge of the assembly surface and the displacement sensor. A measurement point for calculating the reference value can be set by the user.

When the distance value measured from the displacement sensor is converted using the reference value, it can be used as a scale (hereinafter, referred to as a warpage value) indicating a degree of absolute warpage of the substrate. The warpage value can be calculated as shown in Equation 1 below.

Warpage value=reference value−distance value measured by displacement sensor  [Equation 1]

According to above Equation 1, when the warpage value has a positive value, it can be seen that the substrate is warped in a direction opposite to gravity. In addition, when the warpage value has a negative value, it can be seen that the substrate is warped in the gravity direction. The controller 172 can determine whether the substrate is raised or lowered according to signs of the warpage value.

In one embodiment, the displacement sensor senses a distance between each of several points, such as 25 points (e.g., warpage values) of the substrate and the displacement sensor. Thereafter, the controller 172 can convert the sensed values into a warpage value and control a vertical movement distance and a vertical movement direction of the substrate based on maximum and minimum values among the 25 warpage values. Specifically, when an absolute value of the maximum value among the 25 warpage values is greater than that of the minimum value, the controller 172 determines that the substrate is entirely warped in the opposite direction to gravity, and controls the substrate chuck such that the substrate is raised. On the other hand, when an absolute value of the minimum value among the 25 warpage values is greater than that of the maximum value, the controller 172 determines that the substrate is entirely warped in the gravity direction, and controls the substrate chuck such that the substrate is lowered.

Since an increase in a depth at which the substrate is submerged in the fluid increases buoyancy acting on the substrate, the controller 172 can increase the vertical movement distance of the substrate as the warpage value of the substrate increases. In one embodiment, when an absolute value of the maximum value among the 25 warpage values is greater than that of the minimum value, the controller 172 determines a rising distance of the substrate in proportion to the absolute value of the maximum value. On the other hand, when an absolute value of the minimum value among the 25 warpage values is greater than that of the maximum value, the controller 172 determines a lowering distance of the substrate in proportion to the absolute value of the minimum value.

After the substrate is submerged in the fluid at a predetermined depth, the controller 172 can re-measure a degree of warping of the substrate using the displacement sensor. Thereafter, the controller 172 determines whether to raise or additionally lower the substrate according to a re-measurement result. In one embodiment, the controller 172 can repeat the above-described process until at least one of the maximum value and the minimum value of the warpage value is within a predetermined value.

In another embodiment, the controller 172 can determine a depth at which the substrate is submerged in the fluid based on experimental data with respect to the substrate. Specifically, before the substrate is submerged in the fluid, a degree of warping of the substrate is sensed by the displacement sensor while the substrate is lowered at a predetermined distance. Even after the substrate is submerged in the fluid, the degree of warping of the substrate is sensed by the displacement sensor while the substrate is lowered at a predetermined distance. When such sensing is repeated, it is possible to calculate a correlation between a submerged depth of the substrate and an amount of change in the warpage of the substrate. Such an experiment can be performed for each type of substrate.

When a specific type of substrate is used for self-assembly, the controller 172 senses a degree of warping of the specific type of substrate, and then calculate the depth at which the substrate is submerged in the fluid based on the sensing result and experimental data on the specific type of substrate. Thereafter, the controller 172 controls the substrate chuck such that the substrate is submerged in the fluid by the calculated depth. According to the above-described method, since it is not necessary to repeatedly sense the degree of warping of the substrate, the process time can be shortened.

Meanwhile, a correction result of the warpage of the substrate can be used for correcting the warpage of another substrate. Specifically, referring to FIG. 26, in the present disclosure, after the substrate is submerged at a predetermined depth according to the above-described experimental data, a degree of warping of the substrate is re-measured.

At this time, in the present disclosure, a user selects whether to measure the degree of warping of the entire substrate or only a part of the substrate via the input part provided separately in the controller 172 (S201—“Mode selection).

Thereafter, a target position serving as a displacement measurement target and a reference position (reference value calculation target position) serving as a reference for a degree of warping of the substrate are input respectively (S202 to S204) (S202 —“Initial reference position x,y value input”, S203 —“Target input”, S204 —“Reference position input”).

Thereafter, the controller 172 moves the displacement sensor to a predetermined measurement position (S205 —“Move to #1 measurement position”). The displacement sensor senses a distance between the displacement sensor and the substrate (S206 —“Sensor Measurement”). Thereafter, the controller 172 moves the displacement sensor to a next measurement position (S207 —“Move to next position”). Whenever measurement of the displacement sensor is completed, the controller 172 determines whether sensing of all target positions designated by the user is completed (S208 —“Comparison position measurement=All?”), and when the sensing is not completed (No of S208), the controller 172 transfers the displacement sensor to a next measurement position (back to S207).

When sensing of all target positions is completed (Yes of S208), the controller 172 converts the sensing value into a warpage value, and determines whether at least one of the maximum value and the minimum value of the warpage values is within a predetermined range (S209 —“Determination”).

When the warpage values are within the predetermined range (Yes of S209), the controller 172 displays a measurement result on an output part provided separately (S211 —“Measurement value display”), and updates the experimental data controlling the substrate chuck at the time of correcting the warpage of the corresponding substrate (S212 —“Reflect other unit offset value”), and uses at the time of correcting the warpage of another substrate.

On the other hand, when the difference value is out of the predetermined range (No of S209), the controller 172 raises or lowers the substrate (S210 —“Move by correction value”) according to a sensing result, and then repeats operation S205.

Meanwhile, the controller 172 can control the substrate chuck such that a step in which the substrate is in contacted with the fluid and a step in which the substrate is submerged in the fluid are performed stepwise or sequentially. Bubbles can remain on a surface of the substrate in a process in which the substrate is in contact with the fluid. The controller 172 performs control to minimize the bubbles until the substrate is in contact with the fluid, and performs control for applying buoyancy to the substrate after the substrate is completely in contact with the fluid.

Specifically, after the controller 172 lowers the substrate chuck such that the assembly surface of the substrate is in contact with the fluid, the controller 172 can further lower the substrate chuck in a state in which the assembly surface of the substrate is in contact with the fluid.

The controller 172 can differentiate a speed of lowering the substrate until the entire assembly surface of the substrate is in contact with the fluid and a speed of lowering the substrate when the substrate is further lowered.

In one embodiment, the controller 172 controls a substrate chuck such that a speed of lowering the substrate until the entire assembly surface of the substrate is in contact with the fluid is less than that of lowering the substrate chuck when the substrate is further lowered. Accordingly, the controller 172 ensures sufficient time for bubbles to escape to an edge of the substrate in a process of the substrate in contact with the fluid.

Further, in the present disclosure, in order to minimize bubbles formed between the substrate and the fluid, the substrate is contacted obliquely with the fluid when the substrate is in contact with the fluid. For this, the controller 172 controls a vertical moving part and a rotating part provided at the substrate chuck in the process of the substrate in contact with the fluid.

Specifically, the controller 172 controls the vertical moving part to lower the substrate until one end of the assembly surface is in contact with the fluid in a state in which the assembly surface of the substrate is disposed obliquely with the surface of the fluid, and controls the rotating part such that the assembly surface is in contact with the fluid along one direction, sequentially after one end of the assembly surface is in contact with the fluid. Accordingly, the assembly surface of the substrate is in contact obliquely with the fluid. In this process, the bubbles formed between the substrate and the fluid are pushed out of the edge of the substrate and finally pushed out of the substrate. Accordingly, the present disclosure minimizes the bubbles formed between the substrate and the fluid.

Thereafter, the controller 172 controls the vertical moving part to further lower the substrate.

As described above, the controller 172 minimizes bubbles formed between the substrate and the fluid by bringing the substrate into contact with the fluid obliquely in a process of lowering the substrate into the fluid.

Meanwhile, the controller 172 controls movement of the substrate chuck to prevent semiconductor light-emitting diodes from being separated from the substrate after self-assembly is completed. Specifically, after the self-assembly is completed, the substrate should be separated from the fluid, which can cause a problem that the semiconductor light-emitting diode is separated from the substrate due to surface energy between the fluid and the semiconductor light-emitting diodes in a process of separating the substrate from the fluid.

In order to prevent such a problem, the controller 172 raises the substrate chuck submerged in fluid to a predetermined height after the self-assembly is completed, and then the controller 172 can further raise the substrate chuck such that the assembly surface of the substrate is separated from the fluid. Here, it is preferable that the predetermined height is up to a surface height of the fluid.

The controller 172 can differently control a speed of raising the substrate to the predetermined height and a speed of further raising the substrate. In one embodiment, the controller 172 raises the substrate up to the surface height of the fluid at a high speed, and then separates the substrate from the fluid at a relatively slow speed. Accordingly, the present disclosure prevents the previously assembled semiconductor light-emitting diode from being separated from the substrate in the process of separating the substrate from the fluid.

In addition, the controller 172 raises the substrate up to a predetermined height, and then drives the vertical moving part and the rotating part such that the assembly surface of the substrate is separated obliquely from the fluid. Specifically, the controller 172 raises the substrate up to a predetermined height, and then controls the rotating part such that the assembly surface is separated sequentially from the fluid along one direction.

At this time, the controller 172 can control a rotation speed of the rotating part to change depending on a time. Specifically, the controller 172 can increase the rotation speed of the rotating part as time passes so that the substrate is quickly separated from the fluid.

As described above, the present disclosure prevents the previously assembled semiconductor light-emitting diode from being separated from the substrate in the process of separating the substrate from the fluid after the self-assembly is completed.

The present disclosure relates to a substrate chuck 1000 for disposing at an assembly position a substrate S among configurations of the above-described device for self-assembling semiconductor light-emitting diodes.

FIG. 27 is a view showing a warpage phenomenon of a substrate that occurs during loading/unloading of a substrate.

As described above, the self-assembly process can be progressed in the fluid accommodated in the assembly chamber 500. Accordingly, the substrate S can be disposed to be in contact with the fluid at an upper side of the assembly chamber 500, and in particular, the assembly surface on which the semiconductor light-emitting diodes are placed can be disposed so as to face a bottom surface of the assembly chamber 500. In addition, all sides of the substrate S having a rectangular shape can be press-fixed to minimize warping of the substrate S.

Referring to (a) and (b) of FIG. 27, a space (pocket) in which a gas and liquid can be confined between the substrate S and the fluid surface during loading (a) of FIG. 27 and unloading (b) of FIG. 27 of the substrate S can be formed by a fixing member provided in order to press the substrate S at a circumference of the substrate S.

There is a problem that the gas and liquid present in the space can prevent the semiconductor light-emitting diodes C from being assembled on the substrate S, and can separate the semiconductor light-emitting diodes C assembled on the substrate S by instantaneously generating a strong pressure together with a gas flowing therein from the outside when the substrate S is separated from the fluid after the assembly is completed. Accordingly, a self-assembly yield is lowered, and a lot of time was required for a repair process which is a post process.

When loading and unloading the substrate S to the assembly position, the self-assembly device according to the present disclosure include a substrate chuck 1000 formed with microholes hs and hp for sucking or extracting a gas and/or liquid present on the substrate S and a fluid surface or injecting a gas into the substrate S and the fluid surface. Hereinafter, the substrate chuck 1000 which is one configuration of the self-assembly device according to an embodiment of the present disclosure will be described in detail.

FIG. 28 is an enlarged view of a portion in which microholes are formed in a substrate chuck according to an embodiment of the present disclosure, FIG. 29 shows a process of sucking a gas between a substrate and a fluid during loading of a substrate, and FIG. 30 is a process of injecting a gas into between a substrate and a fluid during unloading of a substrate.

The device for self-assembling semiconductor light-emitting diodes according to the present disclosure can be for placing the semiconductor light-emitting diodes C at a predetermined position on the substrate S accommodated in the assembly chamber 500 accommodating the fluid by using electric and magnetic fields.

According to the present disclosure, the self-assembly device can include a substrate support part 1010, a vertical moving part 1020, a rotating part 1030, and a controller 1040, and can include a substrate chuck 1000 for disposing the substrate S at an assembly position of the assembly chamber 500.

Meanwhile, the substrate chuck 1000 can include an integrated vertical and horizontal moving part (see FIG. 11). Hereinafter, however, since vertical movement of the substrate S will be mainly described, the vertical and horizontal moving parts will be referred to as a vertical moving part.

The substrate support part 1010 can support the substrate S on which an assembly electrode is formed, and can be formed in a structure capable of pressing and fixing four sides of the substrate S having a rectangular shape. In addition, the substrate support part 1010 can include an electrode connection part connected to the assembly electrode formed on the substrate S to generate the electric field on one surface of the substrate S.

According to an embodiment of the present disclosure, when the substrate S is loaded into the assembly position (downward movement of the substrate S) and when the substrate S is unloaded (upward movement of the substrate S), the substrate support part 1010 can include microholes hs and hp for sucking fluid (especially gas) confined in a space formed by a press-fixing structure of the substrate S or injecting gas into the space. The detailed structure of the substrate support part 1010 according to the embodiment of the present disclosure will be described later.

The vertical moving part 1020 can move the substrate S in a vertical direction, that is, upwardly and downwardly. A position of the substrate S can be adjusted with respect to the fluid by vertical movement. That is, the substrate S can move vertically to be in contact with or separated from the fluid. Since the substrate S moves in a state supported by the substrate support part 1010, the vertical moving part 1020 can substantially move the substrate support part 1010 in the vertical direction.

The rotating part 1030 can rotate the substrate S. Specifically, the rotating part 1030 can rotate the substrate S around a width direction or a longitudinal direction of the substrate S, and dispose the substrate S not overlapped with the assembly chamber 500 at an upper side of the assembly chamber 500 such that the substrate S is overlapped with the assembly chamber 500 by rotation. Since the substrate S is rotated in a state that is supported by the substrate support part 1010, the rotating part 1030 can substantially rotate the substrate support part 1010.

The controller 1040 can control the above-described configurations to control driving of the substrate chuck 1000. In particular, according to the present disclosure, the controller 1040 can control whether the gas is sucked or injected through the microholes hs and hp according to whether the substrate S is raised or lowered. Such a process can be forcibly progressed to improve a self-assembly yield.

Specifically, when the substrate S is lowered so as to come into contact with the fluid, the controller 1040 can control such that the gas present between the substrate S and the fluid is sucked through suction holes hs of the microholes hs and hp, and when the substrate S is raised so as to be separated from the fluid, the controller 1040 can control such that the gas is injected into between the substrate S and the fluid through injection holes hp.

In addition, when the substrate S is lowered so as to come into contact with the fluid, a liquid present between the substrate S and the fluid (for example, a liquid in the assembly chamber 500) can be sucked and removed together with the gas. Therefore, a separate configuration for sucking the liquid can be provided at the substrate support part 1010, or the liquid can be sucked together with the gas through the suction holes hs.

Further, when the substrate S is lowered so as to come into contact with the fluid, the controller 1040 can control so as to prevent backflow of the gas and liquid sucked through the suction holes hs, and the substrate chuck 1000 can further include a configuration such as a valve as a backflow prevention part.

Hereinafter, a structure of the substrate support part 1010 including the microholes hs and hp according to an embodiment of the present disclosure will be described.

The substrate support part 1010 can include a first frame 1011 for supporting one surface of the substrate S on which the assembly electrode is formed, that is, an assembly surface of the substrate S and a second frame for supporting the other surface of the substrate S. The first frame 1011 and the second frame can be disposed vertically.

According to the present embodiment, the substrate S can be placed at the substrate support part 1010 in a state in which the first frame 1011 is disposed to be positioned at an upper side of the second frame at a position not overlapped with the assembly chamber 500. Thereafter, the rotating part 1030 can rotate the substrate support part 1010 around a width direction or a longitudinal direction of the substrate S such that the vertical positions of the first frame 1011 and the second frame are switched to dispose at an assembly position at which the substrate S and the assembly chamber 500 overlap. That is, the assembly surface of the substrate S can be disposed so as to face the assembly chamber 500 by rotation.

The first frame 1011 for supporting the assembly surface of the substrate S can include a bottom portion 1011′ of which a central portion is opened and a sidewall portion 1011′ formed at a predetermined height along an outer circumference of the bottom portion 1011′.

A region in which the assembly electrode is formed in the assembly surface of the substrate S can be in contact with the fluid via the opened portion of the bottom portion 1011′ when the substrate S is loaded. Meanwhile, the sidewall portion 1011″ can be to prevent the fluid in the assembly chamber 500 from overflowing to the other surface of the substrate S in a state in which a power is applied to the substrate S.

According to one embodiment, the microholes hs and hp can be formed on an inner circumference of the first frame 1011 adjacent to the assembly surface, and can be formed at a predetermined pitch along at least a portion of the inner circumference of the first frame 1011.

For example, the microholes hs and hp can be formed at all four sides of the inner circumference of the first frame 1011, or can be formed on a part of the sides. When the microholes hs and hp are formed at a part of the inner circumference, the microholes hs and hp can be formed at least along the length direction of two sides 1011 a and 1011 b facing each other of the sides forming the inner circumference.

When the microholes hs and hp are formed at the two sides 1011 a and 1011 b facing each other, the microholes hs formed along one side 1011 a of the two sides can be suction holes hs for sucking a gas and/or liquid present between the substrate S and the fluid, and the microholes hp formed along the other side 1011 b can be injection holes hp for injecting a gas into between the substrate S and the fluid.

That is, according to the present embodiment, the microholes hs and hp can perform different functions (suction or injection of a gas) depending on a formation position. The function of the microholes hs and hp can be determined by a method of loading and unloading the substrate S, and an embodiment related thereto will be described later.

Meanwhile, the microholes hs and hp can be a hollow-shaped structure (structure in which one side communicates with the other side) formed through precision machining, and although the microholes hs and hp are exemplified to be formed on the inner circumference of the first frame 1011, they can be formed at various positions of the substrate chuck 1000. In addition, the microholes hs and hp can be processed to a suitable size in consideration of positions in which the microholes hs and hp are formed, characteristics of the self-assembly process, for example, a depth of submerging the substrate S, a material of the substrate S, and the like.

According to an embodiment of the present disclosure, the substrate chuck 1000 can further include a mass flow control part that controls an injection volume and an injection rate of the gas injected through the injection holes hp of the microholes hs and hp. In addition, the mass flow control part can be controlled by the controller 1040, for example, the injection volume and injection rate of the gas by the mass flow control part can be set according to the loading and unloading speed of the substrate S.

According to an embodiment of the present disclosure, the substrate S can be loaded and unloaded while tilted in an oblique state. For example, the controller 1040 can obliquely align one side of the substrate S to be in first contact with the fluid, and move the substrate S downward, and load the other side facing the one side to be in last contact with the fluid in the assembly chamber 500. In case of the unloading process, the substrate can be tilted and moved upward such that one side of the substrate S is first separated from the fluid, and the other side facing the one side of the substrate S can be finally separated from the fluid in the assembly chamber 500.

That is, the controller 1040 can bring the substrate S into contact with the fluid or separate the substrate S from the fluid in a state in which the substrate S is tilted obliquely. When the substrate S is loaded and unloaded in this manner, a time required for the fluid and the substrate S to completely contact or be separated can be maximized. Accordingly, by allowing the remaining gas and liquid in a space between the substrate S and the fluid to gradually escape from the space, so that bubbles formed on the assembly surface of the substrate S can be efficiently removed, and a large volume of gas can be prevented from flowing in from the outside at once to mitigate an impact that can be applied to the substrate S during unloading.

In addition, as in the present embodiment, when forced injection and suction of the fluid through the microholes hs and hp are performed during the loading and unloading process of the substrate S as described above, effects of suppressing bubble formation and impact mitigation can be maximized.

Meanwhile, according to an embodiment of the present disclosure, the microholes hs and hp can be formed at at least a region of the substrate support part 1010 for supporting one side and the other side of the substrate S or a region of the first frame 1011. Here, the region of the substrate support part 1010 or the first frame 1011 can mean a side of the substrate support part 1010 or the first frame 1011 that overlaps one side and the other side of the substrate S.

At this time, the microholes hs and hp formed in the region of the substrate support part 1010 for supporting the other side of the substrate S that is last in contact with or separated from the fluid can perform a function as the suction holes hs.

FIG. 29 shows a gas suction process together with a structure (A: DI drain, B: exhaust line, C: vacuum generator, D: solenoid valve, and E: gas supply part) of a controller 1040 s connected to the suction holes hs.

The controller 1040 s can control such that the gas present between the substrate S and the fluid is sucked through the exhaust line B by creating a vacuum state with the vacuum generator C. At this time, a fluid DI present between the substrate S and the fluid can be removed through the DI drain A. Through such a suction process, the gas or the like present between the substrate S and the fluid can be removed together with the bubbles present at the surface of the substrate S (see (a), (b) and (c) of FIG. 29).

Meanwhile, the microholes hs and hp formed in the region of the substrate support part 1010 for supporting one side of the substrate S that is first in contact with or separated from the fluid can perform a function as the injection holes hp.

FIG. 30 shows a gas injection process together with a structure (A: gas supply part, B: solenoid valve, and C: mass flow control part (MFC)) of a controller 1040 p connected to the injection holes hp.

The controller 1040 p can inject the gas supplied through the gas supply part A into the space between the substrate S and the fluid, and the volume and rate of the injected gas can be controlled by the mass flow control part. Through such an injection process, it is possible to prevent a strong pressure from being applied onto the substrate S during the unloading of the substrate S to prevent the assembled semiconductor light-emitting diodes from being separated from the substrate S. In addition, the gas injected through the injection holes hp can dry a surface of the substrate S accommodated in the fluid (see (a), (b) and (c) of FIG. 30).

Meanwhile, a control of suction and injection of the gas by controller 1040 described above can be performed independently, the configuration of the controller 1040 shown in drawings is merely illustrative, and of course, other configurations that can perform the same function can be made.

As described above, the self-assembly device according to an embodiment of the present disclosure can improve an assembly yield by removing factors that hinder the progress of the self-assembly process, and there is an effect of ensuring reliability of the self-assembly process.

The above-described present disclosure is not limited to the configuration and method of the embodiments described above, and the embodiments can be configured by selectively combining all or part of each of embodiments so that various modifications can be made. 

What is claimed is:
 1. A device for self-assembling semiconductor light-emitting diodes for placing the semiconductor light-emitting diodes at predetermined positions on a substrate by using an electric field and a magnetic field, the substrate being accommodated in an assembly chamber accommodating a fluid, the device comprising: a substrate chuck configured to dispose the substrate at an assembly position, wherein the substrate chuck includes: a substrate support part configured to support the substrate on which an assembly electrode is formed; a rotating part configured to support the substrate support part; and a controller configured to control driving of the substrate chuck, wherein the substrate support part includes micro-holes for injecting a gas between the fluid and the substrate, and wherein the controller controls whether the gas is injected through the micro-holes according to whether the substrate is raised or lowered.
 2. The device for self-assembling semiconductor light-emitting diodes of claim 1, wherein, when the substrate is raised so as to separate from the fluid, the controller controls such that the gas is injected into between the fluid and the substrate through the micro-holes.
 3. The device for self-assembling semiconductor light-emitting diodes of claim 1, wherein micro-holes extract a gas present between the fluid and the substrate.
 4. The device for self-assembling semiconductor light-emitting diodes of claim 3, wherein, when the substrate is lowered to be in contact with the fluid, the controller controls such that the gas present between the fluid and the substrate is extracted through the micro-holes.
 5. The device for self-assembling semiconductor light-emitting diodes of claim 1, wherein the substrate support part includes a first frame for supporting one surface of the substrate on which the assembly electrode is formed, and a second frame for supporting the other surface of the substrate.
 6. The device for self-assembling semiconductor light-emitting diodes of claim 5, wherein the first frame includes a bottom portion having an opened central portion, and a sidewall portion formed at a predetermined height along an outer circumference of the bottom portion.
 7. The device for self-assembling semiconductor light-emitting diodes of claim 6, wherein the micro-holes are formed at a predetermined pitch along at least a part of an inner circumference of the first frame
 8. The device for self-assembling semiconductor light-emitting diodes of claim 6, wherein the micro-holes are formed at least along a longitudinal direction of two sides facing each other among sides forming an inner circumference of the bottom portion.
 9. The device for self-assembling semiconductor light-emitting diodes of claim 6, wherein the micro-holes formed along any one of the two sides facing each other extract the gas present between the fluid and the substrate, and wherein the micro-holes formed along the other side of the two sides facing each other inject the gas into between the fluid and the substrate.
 10. The device for self-assembling semiconductor light-emitting diodes of claim 1, further comprising a mass flow control part is configured to control an injection volume and an injection rate of the gas injected through the micro-holes.
 11. The device for self-assembling semiconductor light-emitting diodes of claim 1, further comprising a vertical moving part configured to move the substrate supported by the substrate support part upwardly and downwardly to adjust a position of the substrate with respect to the fluid.
 12. The device for self-assembling semiconductor light-emitting diodes of claim 1, further comprising an electrode connection part configured to connect to the assembly electrode formed on the substrate to generate the electric field.
 13. A device for self-assembling semiconductor light-emitting diodes for placing the semiconductor light-emitting diodes at predetermined positions on a substrate by using an electric field and a magnetic field, the substrate being accommodated in an assembly chamber accommodating a fluid, the device comprising: a substrate chuck configured to dispose the substrate at an assembly position, wherein the substrate chuck includes: a substrate support part configured to support the substrate on which an assembly electrode is formed; a rotating part configured to support the substrate support part; a moving part configured to move the substrate supported by the substrate support part upwardly and downwardly to adjust a position of the substrate with respect to the fluid; and a controller configured to control driving of the substrate chuck, wherein the substrate support part includes micro-holes for injecting a gas between the fluid and the substrate, and wherein the controller controls whether the gas is injected through the micro-holes according to whether the substrate is raised or lowered.
 14. The device for self-assembling semiconductor light-emitting diodes of claim 13, wherein, when the substrate is raised so as to separate from the fluid, the controller controls such that the gas is injected into between the fluid and the substrate through the micro-holes.
 15. The device for self-assembling semiconductor light-emitting diodes of claim 13, wherein micro-holes extract a gas present between the fluid and the substrate.
 16. The device for self-assembling semiconductor light-emitting diodes of claim 15, wherein, when the substrate is lowered to be in contact with the fluid, the controller controls such that the gas present between the fluid and the substrate is extracted through the micro-holes.
 17. The device for self-assembling semiconductor light-emitting diodes of claim 13, wherein when the substrate is raised or lowered, the rotating part inclines the substrate such that one side of the substrate is in contact with the fluid first or separates from the fluid.
 18. The device for self-assembling semiconductor light-emitting diodes of claim 17, wherein the micro-holes are formed in at least one side of the substrate support part for supporting one side of the substrate and the other side of the substrate support part for supporting the other side of the substrate facing the one side of the substrate.
 19. The device for self-assembling semiconductor light-emitting diodes of claim 3, wherein the rotating part rotates the substrate support part around a width or longitudinal direction of the substrate such that vertical positions of the first frame and the second frame are switched.
 20. The device for self-assembling semiconductor light-emitting diodes of claim 13, wherein the micro-holes are formed at a predetermined pitch along at least a part of an inner circumference of the first frame. 